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Title:
ROTATABLE TOW HITCH FOR A VEHICLE
Document Type and Number:
WIPO Patent Application WO/2005/110781
Kind Code:
A1
Abstract:
Tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part (1) having a hitch ball (4) at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder (71) member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member (71) about two hinge axes (F, G) that are perpendicular to each other, in a movement between an extended operative position and a stowed-away inoperative position, wherein the proximal end portion is provided with a drive cam (8) that is in engagement with drive means for the drive cam.

Inventors:
MARGADANT ARNOUD PHILIP DAAN (NL)
EISING FREDERIK JACOB (NL)
Application Number:
PCT/NL2005/000373
Publication Date:
November 24, 2005
Filing Date:
May 17, 2005
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
BRINK INTERNAT B V (NL)
MARGADANT ARNOUD PHILIP DAAN (NL)
EISING FREDERIK JACOB (NL)
International Classes:
B60D1/54; (IPC1-7): B60D1/54; B60D1/06
Domestic Patent References:
WO2003072375A12003-09-04
Foreign References:
EP1084871A22001-03-21
GB1504643A1978-03-22
US2889155A1959-06-02
DE9109699U11992-01-16
US2544185A1951-03-06
EP1145876A12001-10-17
FR2740080A11997-04-25
US4109930A1978-08-29
US3640550A1972-02-08
DE19859961A12000-07-13
US4078827A1978-03-14
Other References:
See also references of EP 1765612A1
Attorney, Agent or Firm:
Ferguson, Alexander (P.O. Box 266, AW The Hague, NL)
Download PDF:
Claims:
Claims
1. Tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member about at least two rotation axes including an angle with each other, in a movement between an extended operative position and a stowedaway inoperative position, wherein the proximal end portion is provided with a drive cam that is in engagement with drive means for the drive cam.
2. Tow hitch assembly according to claim 1 , wherein the rotation can take place about at least two rotation axes that are perpendicular to each other.
3. Tow hitch assembly according to claim 1 or 2, wherein a first rotation axis is vertical or at a small angle to the vertical.
4. Tow hitch assembly according to claim 3, wherein the first rotation axis is at a small angle to the vertical, considered in a vertical plane of projection transverse to the driving direction of the vehicle.
5. Tow hitch assembly according to claim 4, wherein the first rotation axis is situated in a vertical plane perpendicular to a vertical centre longitudinal plane of the vehicle.
6. Tow hitch assembly according to claim 4 or 5, wherein the first rotation axis slopes upwards towards the side to which the tow hitch member is moved in the movement to the inoperative position.
7. Tow hitch assembly according to any one of the preceding claims, wherein the rotation can take place about a second rotation axis and a third rotation axis, that are horizontal or at a small angle to the horizontal, and may be perpendicular to each other.
8. Tow hitch assembly according to claim 7, wherein the tow hitch member can hinge about the second and third rotation axis for movement between at least one high position and a low position of the tow hitch ball.
9. Tow hitch assembly according to claim 8, wherein the tow hitch member both in the inoperative position and the operative position takes a high position with the tow hitch ball, in which position the tow hitch ball is situated higher than the tow hitch neck which connects thereto.
10. Tow hitch assembly according to any one of the preceding claims, wherein the holder member comprises a bearing housing forming a first cam track for guiding the drive cam in its movement.
11. 1 1 . Tow hitch assembly according to claim 10, wherein the first cam track is substantially Ushaped. 12.
12. Tow hitch assembly according to claim 1 1 , wherein the legs of the Ushape in top view mutually include an angle of approximately 90 degrees.
13. ToW hitch assembly according to claim 10, 1 1 or 1 2, wherein the drive means comprise a drive sleeve provided with an accommodation space for driving engagement of the drive cam.
14. Tow hitch assembly according to claim 13, wherein the accommodation space is formed by a second cam track, for subjecting the drive cam to a movement, wherein the second cam track can be V shaped.
15. 1 5.
16. Tow hitch assembly according to claim 13 or 14, wherein the drive sleeve is situated between the proximal end and the bearing housing.
17. Tow hitch assembly according to claim 13, wherein the accommodation space forms a passage for the drive cam.
18. Tow hitch assembly according to claim 13 or 14, wherein the drive sleeve is situated around the bearing housing.
19. Tow hitch assembly according to claim 13, wherein the first cam track forms a passage for the drive cam.
20. Tow hitch assembly according to any one of the claims 1018, wherein the proximal end portion is provided with an added orienting member and the bearing housing is provided with a guide track for the orienting member.
21. Tow hitch assembly according to claim 19, wherein the orienting member forms a protrusion. 21.
22. Tow hitch assembly according to claim 20, wherein the orienting member comprises a pin and an orienting plate bearing mounted thereon so as to be freely rotatable.
23. Tow hitch assembly according to claim 20, wherein the orienting member comprises a ring that is arranged on the proximal end portion so as to be rotatable about a pin.
24. Tow hitch assembly according to claim 22, wherein the ring is supported on the guide track for movement therealong.
25. Tow hitch assembly according to claim 21 , 22 or 23, wherein the axis of the pin coincides with said second and third rotation axes, in two positions rotated with respect to the first rotation axis.
26. Tow hitch assembly according to any one of the claims 1924, wherein the guide track is arranged at the inside of the bearing housing.
27. Tow hitch assembly according to any one of the claims 1925, wherein the guide track extends concentrically about the first rotation axis.
28. Tow hitch assembly according to any one of the claims 1326, comprising an electromotor for driving the drive sleeve.
29. Tow hitch assembly according to any one of the claims 1326, wherein the drive sleeve is rotatable about the first hinge axis.
30. Tow hitch assembly according to any one of the claims 1028, wherein the first cam track has a substantially vertically oriented first end portion which defines the position of the first cam in the operative position of the tow hitch member.
31. Tow hitch assembly according to any one of the claims 1029, wherein the first cam track has a substantially vertically oriented second end portion which defines the position of the first cam in the inoperative position of the tow hitch member.
32. Tow hitch assembly according to any one of the preceding claims, wherein the proximal end portion has a spherical end.
33. Tow hitch assembly for a vehicle, having a tow hitch member that comprises a spherical proximal end portion that is provided with a protrusion, wherein the spherical end portion is accommodated in a relatively stationary sphere bearing housing, provided with a first cam track for guiding the protrusion.
34. Tow hitch assembly according to claim 32, wherein furthermore a drive sleeve is present that is provided with a second cam track for the protrusion and drivingly engages it for rotating the tow hitch member between an extended operative position and a stowedaway inoperative position.
35. Tow hitch assembly according to claim 33, wherein the drive sleeve is positioned for rotation about a substantially vertical axis.
36. Tow hitch assembly for a vehicle, having a tow hitch member comprising a proximal end portion provided with a protrusion, and accommodated in a relatively stationary bearing housing that is provided with a first cam track for guiding the protrusion for rotation of the proximal end portion and thus the tow hitch member in at least two directions that are perpendicular to each other.
37. Tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member about at least two axes including an angle with each other, in a movement between an extended operative position and a stowedaway inoperative position, wherein the proximal end portion is provided with a drive cam or control cam and a first and a second guide track for them, wherein the drive cam extends in both guide tracks and both guide tracks have a mutually different course and are movable with respect to each other for movement of the drive cam.
38. Tow hitch assembly according to claim 36, wherein the first guide track is fixedly positioned and the second guide track is movably positioned.
39. Tow hitch assembly according to claim 36 or 37, wherein the first and the second guide tracks are movable with respect to each other by rotation about one single rotation axis.
40. Tow hitch assembly according to claim 38, wherein the drive cam extends radially or with a radial directional component with respect to the rotation axis.
41. Tow hitch assembly according to any one of the claims 3639, wherein the first and second guide tracks are arranged in a first surrounding body, such as hollow body, and a second surrounding body, such as hollow body, respectively, wherein the first body surrounds the second body and the proximal end portion is accommodated in the second body.
42. Tow hitch assembly according to claim 40, wherein the first body is driven and the second body is stationary.
43. Tow hitch assembly according to claim 40, wherein the second body is driven and the first body is stationary.
44. Tow hitch assembly according to any one of the claims 3642, wherein the first guide track is substantially Vshaped and the second guide track is substantially Ushaped.
45. Tow hitch assembly according to any one of the claims 3642, wherein the second guide track is substantially Vshaped and the first guide track is substantially Ushaped.
46. Tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member about at least two rotation axes including an angle with each other, in a movement between an extended operative position and a stowedaway inoperative position, wherein the proximal end portion is provided with a drive cam or control cam and at least one driven guide track for it for driving the drive cam.
47. Tow hitch assembly according to claim 45, wherein the rotation axes form an intersection in the proximal end portion, which intersection forms a multiple point of rotation, and wherein the drive cam is situated at a side of the intersection facing away from the tow hitch neck.
48. Tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member, provided with one or more of the measures described in the claims 1 46.
49. Tow hitch assembly according to any one of the preceding claims, wherein a first rotation axis is at a small angle to the vertical, considered in a vertical plane of projection transverse to the driving direction of the vehicle, wherein the tow hitch member is rotatable about a combined point of rotation, wherein the tow hitch neck in an area including and connecting to the tow hitch ball, is situated in a vertical centre longitudinal plane of the vehicle, wherein the point of rotation is also situated in said centre longitudinal plane.
50. Tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a rotary connection with each other for rotation of the tow hitch member about a point of rotation about more than one rotation axis, wherein a first rotation axis is at a small angle to the vertical, considered in a vertical plane of projection transverse to the driving direction of the vehicle, wherein the tow hitch neck in an area including and connecting to the tow hitch ball, is situated in a vertical centre longitudinal plane of the vehicle, wherein the point of rotation is also situated in said centre longitudinal plane.
51. Tow hitch assembly according to claim 48 or 49, wherein the proximal end portion, considered in projection on a vertical transverse plane of the vehicle, with its axis coincides with the projection of the first rotation axis.
52. Vehicle provided with a tow hitch assembly according to any one of the preceding claims.
53. Tow hitch assembly provided with one or more of the characterising measures described in the attached description and/or shown in the attached drawings.
Description:
ROTATABLE TOW HITCH FOR A VEHICLE

BACKGROUND OF THE INVENTION

The invention relates to a tow hitch assembly of which the part provided with the tow hitch ball is rotatable between an operative position extended from a vehicle and a stowed-away inoperative position.

Many embodiments of such tow hitch assemblies are known.

From British patent specification 1 .504.643, US patent specification 2.889.1 55 and German utility model 91 .09699.5 an embodiment is known in which the rotatable part can be rotated about a horizontal axis of rotation that is oriented transverse to the vertical centre longitudinal plane of the vehicle. ' From US patent specification 2.544.185 and European patent application 1 .145.876 an embodiment is known in which the rotatable part can be rotated about a horizontal axis of rotation extending in the longitudinal direction of the vehicle, and moreover can be shifted in said direction. From French patent application 2.740.080, US patent specification 4.109.930 ad German utility model 91 .09699.5 an embodiment is known in which the rotatable part can be rotated about a vertical axis of rotation.

From US patent specification 3.640.550 an embodiment is known in which the rotatable tow hitch member is rotatable about a horizontal axis of rotation that is oriented inclined to the vertical centre longitudinal plane of the vehicle.

From German patent application 198 59 961 an embodiment is known in which the rotatable tow hitch member is rotatable about an axis of rotation that is oriented inclined to a vertical transverse plane of the vehicle.

From US patent specification 4.078.827 an embodiment is known in which the rotatable part can be rotated about an axis of rotation that is oriented inclined with respect to a vertical centre longitudinal plane of the vehicle and slightly inclined with respect to a vertical transverse plane of the vehicle.

From German patent application 198 26 618 an embodiment is known in which a straight end member of the rotatable part is provided with a cam track in which a fixed cam engages, so that the rotatable part can be slid up and down and can also be rotated about a vertical axis of rotation. A comparable motion, however this time consecutively, that means vertically linearly downwards - rotation in a horizontal plane - and vertically linearly upwards again, is known from German patent application 100 04 523.

From European patent application 1 .090.782 an embodiment is known wherein the rotatable part, during transfer from the operative position to the inoperative position, can consecutively be pulled downwards, then can be rotated upwards over 90 degrees about a horizontal axis of rotation situated in the centre longitudinal plane of the vehicle and finally can be rotated about a vertical axis of rotation over again 90 degrees.

The known tow hitch assemblies with combined translation-rotation are complex and therefore failure prone.

The known tow hitch assemblies with combined translation-rotation moreover are not easy to adapt to specific conditions of a vehicle model.

It is an object of the invention to provide an embodiment of a tow hitch assembly having a rotatable tow hitch member that at least improves on one of the said disadvantages.

It is a further object of the invention to provide an alternative embodiment of a tow hitch assembly having a rotatable tow hitch member.

It is a further object of the invention to provide a tow hitch assembly having a rotatable tow hitch, with which adjustment to a desired motion is easy.

It is a further object of the invention to provide a tow hitch assembly having a rotatable tow hitch which is simple as regards build-up and which also in the long run is able to operate reliably.

SUMMARY OF THE INVENTION From one aspect the invention provides a tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member about at least two rotation axes including an angle with each other, in a movement between an extended operative position and a stowed-away inoperative position, wherein the proximal end portion is provided with a drive cam that is in engagement with drive means for the drive cam.

In this way a compact and simple arrangement can be realised for rotation of the tow hitch member, which is bearing mounted and driven at its inner end. The bearing housing with first cam track can easily be adjusted to the vehicle type in question, so that use can be made of a universal tow hitch member having a proximal end provided with a drive cam.

In one embodiment the rotation can take place about at least two rotation axes that are perpendicular to each other.

A first rotation axis can be vertical or at a~small angle to the vertical. The first rotation axis can be at a small angle to the vertical, considered in a vertical plane of projection transverse to the driving direction of the vehicle. The first rotation axis can be situated in a vertical plane perpendicular to a vertical centre longitudinal plane of the vehicle. The first hinge axis may slope upwards towards the side to which the tow hitch member is moved in the movement to the inoperative position. The tow hitch ball will in case of rotation about said axis also move slightly downwards. In one embodiment the rotation can take place about a second rotation axis and a third rotation axis, that are horizontal or at a small angle to the horizontal, and may be perpendicular to each other.

The tow hitch member can hinge about the second and third rotation axis for movement between at least one high position and a low position of the tow hitch ball. In this way the movement towards/from the operative position can take place about the second axis and the movement from/towards the inoperative position about the third axis.

In one embodiment the second and the third rotation axis are formed by the same parts, which however are then rotated about the first axis.

The tow hitch member can be hingable about a second rotation or hinge axis for movement between at least one high position and a low position of the tow hitch ball.

The tow hitch member may both in the inoperative position and the operative position take a high position with the tow hitch ball, in which position the tow hitch ball is situated higher than the tow hitch neck, which connects thereto.

In one embodiment the holder member comprises a bearing housing forming a first guide track or cam track for guiding the drive cam in its movement. The first cam track can be substantially U-shaped, wherein the legs define the position of the drive cam in both positions.

The legs of the U-shape may in top view mutually include an angle of approximately 90 degrees.

In a further embodiment the drive means comprise a drive sleeve provided with an accommodation space for driving engagement of the drive cam. Such a drive sleeve is a part that can easily be adjusted to the desired movement and can simply be engaged for drive. The accommodation space can be formed by a second guide track or cam track, for subjecting the drive cam to a movement, which track can be V-shaped.

In a first further development the drive sleeve is situated between the proximal end and the bearing housing. The accommodation space may then form a passage for the drive cam.

In a second further development the drive sleeve is situated around the bearing housing. The first guide track or cam track can then form a passage for the drive cam.

In a further embodiment the proximal end portion is provided with an added orienting member and the bearing housing is provided with a guide track for the orienting member. The orienting member may form a protrusion such as a pin having an orienting plate bearing mounted thereon so as to be freely rotatable. Alternatively the orienting member may comprise a ring that is arranged on the proximal end portion so as to be rotatable about a pin. The orienting plate or the ring can be supported on the guide track for movement therealong.

In one embodiment the axis of the pin coincides with said second and third rotation axes, in two positions rotated with respect to the first rotation axis.

In a simple embodiment the guide track is arranged at the inside of the bearing housing.

The guide track may extend concentrically about the first rotation axis. The tow hitch assembly may comprise an electromotor for driving the drive sleeve. One motor will suffice for the movement of the tow hitch between the inoperative position and the operative position.

The drive sleeve can be rotatable about the first hinge axis.

In one embodiment the first cam track has a substantially vertically oriented first end portion which defines the position of the first cam in the operative position of the tow hitch member. In one embodiment the first cam track has a substantially vertically oriented second end portion which defines the position of the first cam in the inoperative position of the tow hitch member. When present, the second cam track may then be substantially V-shaped.

In one embodiment the proximal end portion is spherical. By having the rotation take place about a ball hinge, all movements are concentrated on one single point, as a result of which the construction can be designed simple and as little failure-prone as possible.

The orienting of the tow hitch member can be carried out with the first cam itself. In one embodiment it is provided that the spherical end portion and the bearing housing are provided with a second cam and third cam track that are cooperating with each other for orienting the spherical end portion in the bearing housing, as a result of which the stability can be enhanced. It is preferred then that the second cam is provided on the spherical end portion and the third cam track is provided on the bearing housing, so that the latter can remain simple as regards construction.

From a further aspect the invention provides a tow hitch assembly for a vehicle, having a tow hitch member that comprises a spherical proximal end portion that is provided with a protrusion, wherein the spherical end portion is accommodated in a relatively stationary sphere bearing housing, provided with a first cam track for guiding the protrusion.

Preferably a drive sleeve is present which is provided with a second cam track for the protrusion and drivingly engages it for rotating the tow hitch member between an extended operative position and a stowed-away inoperative position.

Preferably the drive sleeve is positioned for rotation about a substantially vertical axis.

From a further aspect the invention provides a tow hitch assembly for a vehicle, having a tow hitch member comprising a proximal end portion provided with a protrusion, and accommodated in a relatively stationary bearing housing that is provided with a first cam track for guiding the protrusion for rotation of the proximal end portion and thus the tow hitch member in at least two directions that are perpendicular to each other.

From a further aspect the invention provides a tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member about at least two axes including an angle with each other, in a movement between an extended operative position and a stowed- away inoperative position, wherein the proximal end portion is provided with a drive cam or control cam and a first and a second guide track for them, wherein the drive cam extends in both guide tracks and both guide tracks have a mutually different course and are movable with respect to each other for movement of the drive cam. In this way a simple embodiment for the drive of the cam at the tow hitch can be realised. The first guide' track can be fixedly positioned and the second guide track can be movably positioned.

The first and the second guide tracks can be movable with respect to each other by rotation about one single rotation axis. The drive cam can extend radially or with a radial directional component with respect to the rotation axis.

The first and second guide tracks can be arranged in a first surrounding body and a second surrounding body, respectively, wherein the first body surrounds the second body and the proximal end is accommodated in the second body. The first body can be driven and the second body can be stationary. Alternatively the second body can be driven and the first body can be stationary. The surrounding bodies can each be hollow.

The first guide track can be substantially V-shaped and the second guide track can be substantially U-shaped or the second guide track can be substantially V-shaped and the first guide track can be substantially U-shaped.

From a further aspect the invention provides a tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member about at least two rotation axes including an angle with each other, in a movement between an extended operative position and a stowed-away inoperative position, wherein the proximal end portion is provided with a drive cam or control cam and at least one driven guide track for it for driving the drive cam.

The rotation axes may form an intersection in the proximal end portion, which intersection forms a multiple point of rotation, and wherein the drive cam is situated at a side of the intersection facing away from the tow hitch neck.

From a further aspect the invention provides a tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member, provided with one or more of the measures described above.

In all the aforementioned embodiments the first rotation axis may be at a small angle to the vertical, considered in a vertical plane of projection transverse to the driving direction of the vehicle, wherein the tow hitch member is rotatable about a multiple or combined point of rotation, wherein the tow hitch neck in an area including and connecting to the tow hitch ball, is situated in a vertical centre longitudinal plane of the vehicle, wherein the point of rotation is also situated in said centre longitudinal plane.

From a further aspect the invention provides a tow hitch assembly for a vehicle, having a tow hitch member which at a distal end portion is provided with a neck part having a hitch ball at its end and which with a proximal end portion is connected to a holder member to be attached to the vehicle, wherein the holder member and the proximal end portion form a hinge connection with each other for rotation of the tow hitch member about a point of rotation about more than one rotation axis, wherein a first rotation axis is at a small angle to the . vertical, considered in a vertical plane of projection transverse to the driving direction of the vehicle, wherein the tow hitch neck in an area including and connecting to the tow hitch ball, is situated in a vertical centre longitudinal plane of the vehicle, wherein the point of rotation is also situated in said centre longitudinal plane.

The proximal end portion, considered in projection on a vertical transverse plane of the vehicle, can with its axis coincide with the projection of the first rotation axis.

The aspects and measures described and/or shown in the application may where possible also be used independent from each other. Said individual aspects may the subject of divisional .patent applications related thereto.

SHORT DESCRIPTION OF THE DRAWINGS

The invention will be elucidated on the basis of the exemplary embodiments shown in the attached drawings, in which:

Figure 1 shows a tow hitch member of an exemplary embodiment of a tow hitch assembly according to the invention;

Figure 1 A shows a detail of a spherical proximal end of the tow hitch member of figure 1 ;

Figure 2 shows in exploded condition an upper member and a lower member of a bearing housing in the exemplary embodiment of the tow hitch assembly according to the invention; Figure 3 shows a view of a drive casing or drive sleeve in the said tow hitch assembly;

Figure 4 shows a view in perspective of the parts of the figures 2 and 3 in assembled condition;

Figures 5A-D show a schematic view of consecutive conditions of the tow hitch member according to the preceding figures, between an operative position and an (almost) inoperative position;

Figure 6 shows the tow hitch assembly of the preceding figures, in the inoperative position;

Figures 7A-D show an isometric view, a side view, a top view, and a front view, respectively, of an alternative embodiment of a tow hitch assembly according to the invention;

Figures 8A-D show an isometric view, a side view, a rear view and a cross-section, respectively, of a tow hitch member of the tow hitch assembly according to the figures 7A-D;

Figures 9A and 9b show cross-sections according to arrows IXA and IXB in figure 7C;

Figures 10A and 10B show an isometric view and a side view, respectively, of a drive part for the tow hitch member of the tow hitch assembly according to the figures 7A-D;

Figures 1 1 A and 1 1 B show an isometric view and a cross-section, respectively, of a bearing part for the tow hitch member in the tow hitch assembly according to the figures 7A-D; Figures 12A-G show an isometric view, a top view, four cross-sections and a side view, respectively, of a drive casing for the tow hitch assembly according to the figures 7A-D;

Figures 13A-G show an isometric view, a side view, a horizontal cross- section, a top view, a cross-section, a longitudinal section and a bottom view, respectively, of a lower member of a bearing housing for the tow hitch assembly of the figures 7A-D;

Figures 14A-H show an isometric view, a bottom view, two cross- sections, a top view and three cross-sections of an upper member for cooperation with the lower member of a bearing housing for the tow hitch assembly according to the figures 7A-D; and

Figures 1 5A-K show consecutive stages in a movement of the tow hitch member of the tow hitch assembly according to figures 7A-D from an operative position to an inoperative position.

DETAILED DESCRIPTION OF THE DRAWINGS

Tow hitch member 1 in figure 1 is in this example substantially U- shaped having a proximal portion 2, a tow hitch ball 4 and a neck 3 extending in between them. The proximal portion 2 is provided with a recess 5 in its upper end, in which neck part/attachment part 6 of a bearing sphere 7 is attached, in a way that is not further shown. When assembling the desired sphere 7/neck 6 can be selected for the tow hitch member 1 in question, adjusted to the desires and/or constructional conditions.

As indicated in figure 1 A the spherical bearing member 7 is provided with recesses 9, 10a and 10b. Recess 9 is intended for partial accommodation of a cylindrical cam 8, and one or both recesses 10a, 10b are intended for accommodation of a pin 12. A guide plate 13 (K) is bearing mounted on the pin 12 by means of a fitting hole 14. The shape of the guide plate 13 is matched to the spherical surface of the sphere 7. The cam 8 projects further from the surface of the sphere 7 than the pin 12 and the guide plate 13 do, as will be further elucidated below.

In figure 2 shows the bearing housing 20 for bearing the spherical bearing member 7. A lower member 21 and an upper member 22 can be distinguished. The lower member 21 comprises a flange 23 and a collar 25 extending therefrom having upper edge 25a, wherein the flange 23 is provided with a number of attachment holes 24. Likewise the collar 25 is provided with a number of attachment holes 26. Within the collar 25 the flange 23 forms annular guide edge 29 for the guide plate 13. Within it there is a through-opening 27 for passage of the attachment member 6 that extends through it with play. The sphere 7 supports rotatably on the side of the edge 29. The collar 25 is provided with a recess 28, limited by upwardly inclining edges 28a, 28c and a horizontal edge 28b.

The upper member 22 is substantially truncated conical, having an upper wall 33 provided with a hole 34 and a conical casing 30. In the conical casing 30 two recesses 31 a, 31 b are provided that are each formed symmetrically with respect to radial planes and that are parallel to each other and bounded by U-shaped edges 32a, 32c. In between them the casing 30 is bounded at the bottom edge by an edge 32b. The upper member 22 is furthermore provided with attachment holes 36.

When the upper member 22 is placed with the bottom edges 32b, d on the upper edge 25a of the lower member 21 and is attached to the lower member 21 by means of bolts extending through holes 24 and 26, the edges 32a, 32c smoothly merge into edges 28a, 28c, respectively. Either a U-shaped or a V-shaped track has then been formed in which the cam 8 can be guided.

Figure 3 shows the drive casing 40 in which can be distinguished a circle cylindrical casing member 41 a truncated conical casing member 44 and an upper wall 42, in which is a hole 43, for accommodation of a bearing pin 48 (figure 4) which can also extend through hole 34 of the upper member 22 of the bearing housing 20.

Near the bottom edge the casing member 41 is provided with a circumferential groove 49 for a drive belt 56 to be discussed in figure 4. In the conical casing member 44 and the cylindrical casing member 41 a substantially V-shaped duct or groove 47 with turned ends has been left open, which may be symmetrical with respect to a radial or axial plane of the drive casing 40, in which can be distinguished turned ends 46a, 46e, downwardly inclining sections 46b, 46d, and bottom section 46c. The groove 46 is bounded by edges 47, 47a-e for guiding the cam 8. The drive casing 40 is provided with a bottom edge 45.

When assembling this exemplary embodiment of a tow hitch assembly according to the invention, first the spherical bearing member 7 is placed in the lower member 21 of the bearing housing 20, and subsequently the upper member 22 is attached thereto. The sphere 7 fits rotatably in the thus formed bearing housing 20 which almost fully envelops the sphere 7. Subsequently the drive casing 40 is placed over it, wherein the bottom edge 45 supports on the flange 23. The pin 48 is inserted through the holes 34 and 43.

Prior to mounting in a vehicle a drive (figure 4) is added. The drive 50 shown in figure 4 comprises a support plate 51 , which by means of bolts extending through holes 57a can be attached to the lower member 21 of the bearing housing 20. Mounting housing 52, on which an electromotor 53 has been placed, is placed on the support plate 51 . At its drive pin, the electromotor 53 is provided with a drive wheel 55. On the plate two guide rollers 54a, 54b are furthermore arranged. In the said groove 49 of the drive casing 40 an endless drive belt or drive band 56 is placed, which runs about the wheels 54a, 54b and for drive is engaged by drive wheel 55. When the drive wheel 55 is rotated in the direction A, the drive casing 40 will also be rotated in the direction B. Said rotation (H) takes place about axis S, which axis S coincides with said holes 34, 40 and 27.

The tow hitch assembly according to this example is suitable to be placed with the assembled end 50 in a vehicle 70, see figures 5A-D, particularly in a cavity 74 provided in the rear bumper 72 of the vehicle 70, of which the chassis cross bar 71 is shown. The bearing housing 20, particularly the flange 23 may by means of the holes 24 be fixedly attached to the bumper 72 and via this one to the chassis. Operation lines and feed lines for the motor 53 are not shown.

Figure 5A shows the longitudinal direction D of the vehicle 70. It is furthermore shown that the axis S is vertically oriented. It is furthermore shown that the centre point M of the bearing sphere 7 is confined in the bearing housing 20 in a snugly fitting and rotatable manner. Guide plate 13 may then come into engagement with the edge 29, and thus be moved over it by its own free rotatability about pin 12. Cam 8 extends through the groove/duct formed in the bearing housing 20 by recesses 31 a, 31 b, 28, as well as through the groove/duct 46 in the drive casing.

Figure 5A shows that the sphere 7 can in principle be rotated about three axes that are perpendicular to each other, namely rotation in the directions E, F and G. Figure 5A shows the operative position. The cam 8 is then in the turned end section 46e of the groove 46. Suitable means can provide a locking of the cam 8 in that position.

For transferring the tow hitch member 1 to the inoperative position the electromotor 53 is actuated. As a result the drive belt 56 is driven, due to which the casing 40 rotates about axis S, in the direction H. The cam 8 will first of all -relatively- leave end section 46e. Subsequently the cam 8 comes in the downwardly inclined groove section 46d, and is thereby urged downwardly inclined. Said movement is made possible by the vertically oriented recess 31 b in the upper member 22 of the bearing housing 20. The tow hitch member 1 will here rotate about centre point M in the direction F in the centre longitudinal plane of the vehicle 70.

In case of further rotation in the direction H of the drive casing 40 (figures 5B, 5C) the cam 8 is moved further downwards in section 46d, and along the declining edge portion 28a of the collar 25 of the lower member 21 of the bearing housing 20. With a combined rotation in the directions F and G a rotation in the direction E is carried out. The cam 8 runs over the edge 28a until in the recess 28 (figures 5C,D). This continues until the cam 8 is in the groove section 46c, supported by edge portion 28b of bearing housing 20.

Then the situation shown in figure 5D is reached, in which the ball 4 has reached the lowermost position, and has as it were been turned under the bumper 7. The cam 8 has then also abutted the edge 28c on the collar 25 of the lower member 21 . In case of further rotation of the drive casing in the direction H the cam 8 is first urged upwards by the groove section 46b under slight further rotation with a combined rotation (due to the inclined edge 28c) and then, after the cam 8 contacts the bounding edge 32c, is urged straight upwards in the direction J, in the -fixed- bearing housing 20, in order to be fully accommodated in recess 31 a. In case of further rotation of the drive casing 40 the cam 8 then finally ends in the turned end section 46a, in order to be locked there.

The situation shown in figure 6 is then achieved, in which the ball 4 has been moved through an opening 73 disposed in the rear bumper 72 for that purpose.

It will be understood that due to design of the groove 46 and the recesses 28, 31 a, 31 b forming the guide track for the cam 8 in the bearing housing 20, any desired rotation of the tow hitch member 1 can be realised. The shape of the tow hitch member, the location and design of the rear bumper and the other parts of the vehicle can be adjusted to.

Locking of the tow hitch in the operative position and an inoperative position can also take place by using the electromotor.

When it is desired to transfer the tow hitch from the inoperative position to the operative position again, the drive motor 50 is actuated in reverse direction. The drive casing 40 will be rotated in the direction opposite the direction H about the axis S. Movement of the tow hitch member 1 then takes place in reverse direction.

The tow hitch member according to the invention is easy to build up. The parts can easily be replaced or adjusted to the desired movements. The bearing with the proximal end, in this case spherically accommodated in the bearing housing 20, is simple and reliable. The spherical end portion 7 moreover here offers a large freedom of rotation that can be utilised for adjustment to the desired movement. The location of the cam 8 and the pin(s) 12 and the shape of the groove 46 can easily be adjusted to each other. The cam 8 and the pin 12 can be situated at almost any desired location of a sphere plane, depending on the design. The sphere 7 offers a reliable bearing having a high strength.

The tow hitch assembly 100 according to figures 7A-D comprises a tow hitch member 101 which in this example is substantially U-shaped, having a proximal portion 102, a tow hitch ball 104 an a neck 103 extending therebetween. The proximal portion 102 is rotatably accommodated in a bearing housing 120, having a lower member 121 and an upper member 122, which by means of bolts are attached onto each other. On top of the bearing housing an electromotor 153 is disposed, with which a worm roller 155 is rotated. From the upper member 122 of the bearing housing 120 a shaft 148 extends, on which in a rotation-fixed manner a worm wheel 156 is attached, which is in driving engagement with the worm roller 1 55, for rotation in the directions A about axis S.

The tow hitch member 101 is further shown in the figures 8A-D. The proximal portion 102 is provided with a cam 102a disposed at the inner side of the U-form, and with a drive cam or control cam 108 at the end. In its proximity the proximal portion 102 is provided with a transverse through-bore hole 109, that is perpendicular to the axis W of the drive cam 108. In the cross-section of the figure 8B said line W coincides with the line S1 , the axis of the proximal portion 102.

As can be seen in the figures 8C and 8D the tow hitch member 101 is shaped in a particular way, wherein the portions 102, 103b and 103a with ball 104 with their axes are not situated in one plane. For instance the portion 103b is at an obtuse angle to the portion 102 and the portion 103a is at an obtuse angle to the portion 103b, yet also at an angle to portion 102. This is made visible in the figures 8C and 8D with axis S1 of portion 102, which is at an angle α to the axis V of portion 103a, whereas the line V is at an angle β to the line S2, the axis of portion 103b.

This has to do with the arrangement shown in figure 7D and figures 9A and 9B, cross-sections in figure 7C. In figure 7D the portion of the tow hitch member 101 that is engaged for use, for instance for coupling to a caravan, is placed in vertical alignment, wherein the axis V considered in projection on the plane of drawing coincides with the vertical. The axis S1 of portion 102 in the plane of projection (vertical plane, transverse to the direction of movement of the vehicle to which the tow hitch assembly 100 has been attached), coincides with the rotation axis S. Said rotation axis S therefore is inclined with respect to the vertical. In a vertical plane of projection transverse to the plane of drawing of figure 7D the rotation axis S may indeed coincide with the vertical (in projection). With the rotation axis S, also the bearing housing 120 is positioned in a tilted way, in this case at the angle α to the horizontal H, wherein the line T in figure 7D is shown as reference for the direction in which the bearing housing is inclined. All this results in the portion 103a being situated in the centre longitudinal plane M, and the same applies to the point of rotation for the tow hitch, on the intersection of the line S and the axis of the bearing pin 1 10 yet to be discussed.

The not further shown attachment means in the vehicle are adjusted to said inclined position of the bearing housing 1 20. By way of example the angle α may be 7 degrees and the angle β 10 degrees. In another example these angles may be approximately 4 and 12 degrees, respectively. Because of the angle between the proximal portion 102 and the portion 103a/104 it is achieved that in case of a rotation from the operative position to the inoperative position, in case of rotation about axis S, the upper side 104 of the tow hitch ball 104 is moved with a directional component in downward direction. As a result the tow hitch ball 104 will be able to move underneath past a bumper sooner.

In the cross-sections of figures 9A and 9B the composition of among others the bearing housing 120 is shown, in which it can be seen that the drive cam 108 is confined between the upper member 122 of the bearing housing 120, thereby accommodated in recess 131 a, and is downwardly stopped by edge 147a of drive sleeve 140.

In the cross-section according to figure 9B it can be seen that the upper member 122 and the lower member 121 define a cavity 120', in which further bearing parts have been accommodated, namely a drive casing 140, shown in the figures 1 2A-G and a bearing part 1 13, shown in the figures 1 1 A, B. It can be seen that a bearing pin 1 10 extends through the bore hole 109, which bearing pin is fixedly attached therein and projects to either side in order to really function as a bearing pin.

The bearing part 1 13 by approximation is formed like a circular disk, having a circumferential wall 1 18 and a central, vertical through-cavity 1 15. Transverse to the cavity 1 15 two bore holes 1 14 extend that are able to fittingly yet rotatably accommodate the bearing pin 1 10. The cavity 1 15 is bounded to one side by a wall 1 17, and bounded to the opposite side by a threshold 1 16. The lower side/edge 1 19 of the bearing part 1 13 is suitable to be supported rotatably about its axis on support edge 129 that has been formed in the lower member 121 , also see figures 13D-F.

The bearing part or bearing disk 1 13 is accommodated in drive casing 140 so as to be rotatable about its axis, shown in figure 12A-G. The drive casing 140 forms a circle cylindrical accommodation space 149, accessible from below, for fitting accommodation of bearing part 1 13. When assembling this embodiment the tow hitch, after passing through the passage 123 in the lower bearing housing member 121 can be provided with the bearing disk 1 13 at the proximal end portion 102. It can then be inserted into the bearing part 140, after which the pin 1 10 can be inserted through the duct 146 into the holes 1 14. After that, the upper member 122 can be placed in order to close off the accommodation space 120'. For demounting a tool can be inserted through a hole 143 into the sleeve 140, in order to push the pin 1 10 out of the passages 1 14 and the duct 146.

The drive casing 140 has a circle cylindrical circumferential wall 141 and an upper wall 144 having a conical wall section 145 in the centre. A substantially V-shaped, continuous duct 146 is formed in the walls 141 and 144 (see for instance figure 12G). The V-shape is upwardly defined by lip 144a of the upper wall 144, and portion 141 a of circumferential wall 141 extending downwards therefrom. In the duct 146 can be distinguished end section 146a, inclined section 146b, turning section 146c, inclined section 146d and end section 146e. The duct sections 146a-e are bounded in downward direction by edges 147a-e and in upward direction by edges 147f,g. The specific shape of the duct 146 and its sections depends on the desired rotary movement of the tow hitch member.

In figure 12B the location of a number of cross-sections shown in the figures 12C-F is shown in top view of the drive casing 140.

The drive casing 140 is at the lower side provided with a circumferential support edge 150, that is also able to find support on support edge 129 of the lower member 121 of the bearing housing 120. The lower member 121 of the bearing housing 120, shown in figures 13A-G is substantially elongated block-shaped, having a number of attachment holes for the upper member 122 therein, for attachment to a vehicle and for attachment of the motor 153. The lower member 121 has a vertical through-bore hole 123, in which, considered from top to bottom, several sections 123a-c can be distinguished. In the top member there is question of a cylindrical passage, bounded by wall sections 125a, 125b, 125c and 125d. The wall sections 125a and 1 25d are concentric with respect to the axis S, yet wall section 125a is situated at a larger distance therefrom. In addition two shoulders 125b and 1 25c have been formed at the location of the transitions between the walls sections 125a and 125d. At the lower edge of the wall sections 125a a step 127 has been formed. Said step forms a lower boundary for guiding the drive cam 108 during rotation, when it supports on the edge 147c of the drive sleeve 140. As can be seen in figure 13F said step 127 forms a small elevation with respect to the support edge 129. Said height corresponds with the height of the circumferential wall 141 at the location of edge 147c.

Below the support edge 1 29 passage section 123b is formed, defined by walls 126a-f deflecting downwardly inclined. The shape of said walls can be seen in figure 13D, as well as in figure 13G. In the passage 123b areas 127a, 127b are thus mutually differently oriented at 90 degrees, and widened area 127c is defined.

As can be seen in figure 13G two recesses 164 have been formed in the lowermost part of the passage 1 23b, which recesses are at an angle of 90 degrees. They are in line with the widened areas 127a and b. The recesses 164 are bounded by walls 165a, b.

Further downwards the passage section 123c is surrounded by pending stop edges 161 , 162 for the tow hitch neck and the end positions. As can be seen in figure 9A the recess 164 with inclined side edges 165a,b as regards dimensions is adjusted to the dimensions of the cam 102a.

The upper member 122 of the bearing housing 120, shown in the figures 14A-H, is lid-shaped and at the upper side provided with two lips 180a, 180b having passage 181 a, 181 b, for mounting/guiding the drive motor 153 with drive shaft. As shown in figure 7A the drive motor will furthermore be attached to the lower member 1 21 of the bearing housing 1 20.

The upper member 122 has a conically elevated centre part 133, having a flat central part wherein a hole 134 has been disposed for fitting passage of shaft 148 of drive casing 140.

At the lower side/inner side the upper member 1 22 is provided with two blind recesses 131 a, 131 b, that are oriented at an angle of 90 degrees to each other, wherein in between them recess 131 c has been disposed that is also blind yet more slit-shaped. The specific shape of this blind duct 131 a-c is further shown in the figures 14C-H, and depends on the desired design.

The said parts are adjusted such to each other that the drive cam 108 extends through the duct 146 up into the recesses 131 a-c in the upper member 122 and when necessary in the space which is bounded by the wall sections 125a,b,c and step 127. The drive cam 108 is then fittingly yet movably accommodated in the duct 146.

As can be seen in figures 1 OA and 1 OB the worm wheel comprises a worm wheel surface 158, a bore hole 159 for attachment to shaft 148 (see for instance figure 9B), and a locking ring 157. In the situation shown in figures 7A-D, also shown in figure 15A, the tow hitch member portion 103a is positioned vertical, as indicated before. The proximal portion 102 extends in the bearing part or bearing disk 1 13, with the pin 1 10 inserted through bore hole 109, and in holes 1 14. In principle, when no further parts would be present, the tow hitch would be rotatable with respect to bearing part 1 13 about pin 1 10. The drive cam 108 now extends through duct section 106a (also see figure 1 5B), and in recess 131 a.

If it is desired to rotate the tow hitch member 101 over 90 degrees into an inoperative position, where it is oriented substantially transverse to the driving direction, the motor 153 is excited, as a result of which worm roller 1 55 is driven and thus worm wheel 156 is rotated in rotation about rotation axis S. As a result the shaft 148 is also rotated, and thus also the drive casing 140. Due to engagement of the edge 147f onto the drive cam 108 the latter is urged downwards, see figures 15C and 15D. The cam 102a is guided in this movement by the walls 165a,b of recess 164. The tow hitch member 101 is here rotated about the pin 1 10, in figure 7D parallel to, particularly coinciding with axis T.

Finally the lower surface of the drive cam 108 reaches the edge section 147c, so that further rotation about the pin 1 10 is stopped.

The end of the drive cam 108 has now left the recess 131 a and now is positioned entirely in the duct space bounded by the walls 125a-c and step 127.

The motor 153 remains activated, as a result of which the drive casing, with edge section 147d, will exert a horizontal force on the drive cam 108. The lip 144a with downward projection 141 a however prevents an upward movement of the drive cam 108. As a result thereof the drive cam 140 will take along drive cam 108 in rotation, wherein the drive cam 108 with the projection moves through duct 131 c, and via consecutive movements, shown in figures 15E, 15F and 1 5G ends up in the position shown in figure 15H. The bearing part 1 13 here rotates over the support edge 129, about axis S. Finally the drive cam has arrived in abutment to the shoulder 125c, so that it cannot move further than the 90 degrees or transverse position. The drive motor 1 53 however remains excited, as a result of which the drive casing 140 rotates further about axis S, and the drive cam runs on edges 145d and 145e. The drive cam 108 is now situated under the recess 131 b, and may swing upwards, about the axis Q of the pivot pin 1 10. Said motion is shown in figure 1 51, 1 5J and 15K and 15L, in the latter case with the drive cam 108 accommodated in the duct section 146e.

The cam 102a is now inserted in the other recess 164, fittingly in between its walls 165a,b. The tow hitch is now locked in the inoperative position.

If the tow hitch member 101 has to be transferred from the inoperative position to the operative position the drive motor 153 is excited in opposite direction, as a result of which the motion described above is carried out in reverse order.